The Research of Map Spot Colors Digital Proofing in ... · The Research of Map Spot Colors Digital Proofing in Commercial Prepress System Liu Shide1, Sun Qun1, Wei Bin1, Chen Weiguo2
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The Research of Map Spot Colors Digital Proofing in Commercial Prepress System
Liu Shide1, Sun Qun1, Wei Bin1, Chen Weiguo2
1 The Institute of Surveying and Mapping, Information Engineering University, Zhenzhou, China. 2 Chengdu Surveying and Mapping Unit, Chengdu, China.
Abstract At present, many commercial prepress systems have the
function of spot color proofing. However, there are still many problems when digital proofing system is used to simulate spot colors, great color difference is the severe one. In this article, a method of accurate color matching in map spot colors digital proofing is brought forward based on the analysis of the reasons that caused the huge color difference. According to the colorimetric values of the map spot colors, using the utmost color gamut of the digital proofing device, and making several effective corrections, the color difference between standard color values of map spot colors and the final digital proof is about 1. It shows that the accurate color matching of map spot colors in commercial prepress system is achieved.
1 Introduction The quality of digital proofing has been improving
continually due to the revolution of digital proofing devices and the relevant color measuring devices. The average color differences between the sample of printing and that of digital proof can be nearly 1 or even less than 1 if using proper control methods. The color difference can not be perceived by human naked eyes if the value is nearly 1. Although the general digital proofing system will support spot colors, the matching result is not satisfied when proofing spot colors using present digital proofing system. The main problem is that the color difference is huge. Most digital proofing system can only accept spot colors, and actually the CMYK values are used to output. That explains why the color difference is huge, because the CMYK values are usually transformed according to a certain printing method with a narrower color gamut than spot colors.
How can the accurate color matching be achieved for spot colors by digital proofing in the proofing environment of commercial prepress system? In this paper, the limitations of digital proofing system used to output spot colors proof are analyzed. The data transforming and the stages controlling are effective. As a result, the final average color difference is nearly 1, it is sure that the project of spot color proofing is feasible and practical.
2. Problems on digital proofing system when outputting spot colors and the reasons
The files which describe the colors with L*a*b* values are not always supported by all digital proofing system; most often files with CMYK color mode can only be accepted. The relevant
CMYK values of spot colors are often used when digital proofing, so huge color differences are produced.
2.1 Spot colors digital proofing using MetaDimension Color Proof Pro
18 basic colors of a color code for maps are selected to do the experiment. Among the 18 basic colors, some are spot colors and some are process colors, as they are all expressed by its L*a*b* values and ignored the relevant CMYK values, so they are all considered as spot colors. In Photoshop, the 18 color patches are set with their L*a*b* values, and then transformed to CMYK using the default color settings (U.S. Prepress color settings) and saved as Tiff file.
The device for digital proofing is HP Designjet 5500 with HP inks, Easicolor 517 digital proofing paper; the digital proofing software is Heidelberg Prinect MetaDimension Color Proof Pro (the same below). Digital proofing at this time will simulate CD 102 press. X-Rite 530 is used as color measurement instrument. The average color difference between the original colorimetric data and digital color proof of 18 color patches for maps is greater than 13.
2.2 The analysis of digital proofing The average color difference is over 13. It is huge, of course.
What caused such a huge color difference? The following reasons may be considered:
(1) When the Tiff file is transformed from L*a*b* color mode to CMYK, some color patches that are out of color gamut of U.S. prepress default color settings offset from the original position. The average color differences between the original colorimetric values of the 18 color patches and the transformed ones based on the U.S prepress default color settings is about 1.3, but the average color differences between the original colorimetric values of the 18 color patches and the transformed ones based on custom color settings is less than 0.2. In the custom color settings, the default CMYK color space is replaced by the ICC of HP Designjet 5500.
(2) In the digital proofing settings, the profiles of proofer and press are selected. When digital proofing, color space will be changed to the one of the press. But the color gamut of the 18 color patches is larger then the CD102 press, that’s the main reason that caused the huge color difference.
(3) Of course, some color patches are still in the color gamut of the press after transformation. The ICC of the CD 102 press is not the one used to print the color code for maps, so color differences will produce. It needs certain corrections to achieve better matching result.
Based upon the above analysis, the accurate spot colors digital proofing scheme is formed: (1) Custom color settings in Photoshop, using the ICC profile of relevant digital proofer, in this
experiment, HP Designjet 5500. (2) Only device settings are set in the digital proofing software, use the greater color gamut of the proofer. (3) Several proofing corrections reach the accurate matching result.
3. Scheme of accurate color matching of spot colors proofing
3.1 Custom color settings The color gamut of U.S. prepress default color settings is
smaller than that of the color patches for maps. In order to enlarge the color gamut, the ICC profile of HP Designjet 5500 is used during color setting in Photoshop. The colorimetric values of the original and the transformed with the custom color settings are almost the same. The average color difference is under 0.2.
In Photoshop, the CMYK working space is replaced by the ICC profile of HP Designjet 5500. Other settings remain the same as the U.S. prepress default color settings.
3.2 Settings for digital proofing In this experiment, only the device settings of output plan
template in Heidelberg Prinect MetaDimension or Printready are needed, other parameters of digital proofing will leave unchecked or keep the default settings. Pay more attention to make sure that the “proof” settings must not be checked. Fig 3-1 shows the device settings of spot colors proofing output plan template.
Figure 3-1 Device settings of spot colors proof output plan template
3.3 First correction for spot colors proofing After finishing the above steps of settings, now it is time to do
the first digital proofing for the 18 color patches. X-Rite 530 is used to measure the colorimetric values of the digital proof of 18 color patches. According to the measuring data and original ones, the first correction data will get. The colorimetric data of the first proof and the first correction data are shown in Table 3-1. The first proof is only get by series settings of the proofing environment, the average color difference declines from 13 to 8. With the first correction, we will soon get a more satisfied result.
Table 3-1 Measuring colorimetric data of the first proof and the first correction data Standard Measured First correction data
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3.4 Second correction for spot colors proofing Based on the first correction data, renew the Tiff file in
Photoshop, and then output digital proof for the second time. The
colorimetric data of the second proof and the second correction data are shown in Table 3-2. The average color difference is dropped to nearly 2. The result is good enough.
Table 3-2 Colorimetric data of the second proof and the second correction data Standard Measured Second correction data
3.5 Third correction for spot colors proofing Based on the second correction data, renew the Tiff file in
Photoshop, and then output digital proof for the third time. Measure the colorimetric data and then create the third correction data. The average color difference reaches 1.5. The data table is omitted here because of the limited space.
3.6 Final output of spot colors proofing Based on the third correction data, renew the Tiff file in
Photoshop, then output digital proof for the fourth time and this is also the last time for the spot colors proofing. The colorimetric data of the final proof is shown in Table 3-3. The average color difference reaches 1.1.
Table 3-3 Colorimetric data of the final proof and the color differences Standard Measured
4. Conclusion and further research work The average color difference is getting smaller and smaller, it
proves that the analysis of all the reasons caused the huge color differences at the very first digital proofing is right, and it also
proves the feasibility and practicability of the experiment methods used to output spot colors digital proof.
After several corrections, the average color difference declined from 13 at the very beginning to nearly 1 at the final time, the color difference data is shown in the following line graph, Graph 4-1.
0
5
10
15
1st Proof 2nd Proof 3rd Proof 4th Proof Final Proof
AverageColorDifference
Graph 4-1 Color difference data of five digital proofs
Further research works are as follows: 1. Establish the transformation model for spot colors proofing
to meet the demand of all other spot colors proofing. 2. Verify the matching effect of spot colors proofing by
proofing Pantone spot colors.
References: [1] MetaDimension Color Proof Pro User’s Guide, Edition 09/2004,
[4] Prinect Printready System 3 User’s Guide, Edition 04/2006, Heidelberg.
Author Biography Liu Shide received his BS in printing mechanical engineering
from Beijing Institute of Graphic Communications (1988) and his MS in printing technology from Zhengzhou Institute of Surveying and Mapping (1998). He has worked in the Institute of Surveying and Mapping since 1988. His work has focused on the prepress technology in the graphic arts education, and he is an associate professor in this area.
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